2017
DOI: 10.3389/feart.2017.00016
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Parameterizing Deep Water Percolation Improves Subsurface Temperature Simulations by a Multilayer Firn Model

Abstract: Deep preferential percolation of melt water in snow and firn brings water lower along the vertical profile than a laterally homogeneous wetting front. This widely recognized process is an important source of uncertainty in simulations of subsurface temperature, density, and water content in seasonal snow and in firn packs on glaciers and ice sheets. However, observation and quantification of preferential flow is challenging and therefore it is not accounted for by most of the contemporary snow/firn models. Her… Show more

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Cited by 35 publications
(51 citation statements)
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References 83 publications
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“…1a in Marchenko et al, 2017a) and the last one is derived by minimizing the misfit between temperature profiles measured in April 2015 by the thermistor strings installed in April 2014 and in April 2015. The firn pack at Lomonosovfonna is heavily influenced by the percolation and refreezing of meltwater (Marchenko et al, 2017b), which results in prominent variability of subsurface stratigraphy at the scale of 10 m (Marchenko et al, 2017a).…”
Section: Field Datamentioning
confidence: 99%
See 1 more Smart Citation
“…1a in Marchenko et al, 2017a) and the last one is derived by minimizing the misfit between temperature profiles measured in April 2015 by the thermistor strings installed in April 2014 and in April 2015. The firn pack at Lomonosovfonna is heavily influenced by the percolation and refreezing of meltwater (Marchenko et al, 2017b), which results in prominent variability of subsurface stratigraphy at the scale of 10 m (Marchenko et al, 2017a).…”
Section: Field Datamentioning
confidence: 99%
“…During the first two pe-riods it was once every 3 h; during the fourth period it was once every 1 h. During the third period the frequency varied and was once every 1 h during 17 April-31 July 2014 and 15 April-9 July 2015, once every 3 h during 1 August-31 October 2014 and once every 12 h from 1 November 2014 to 14 April 2015. The strings installed in 2012, 2013 and 2014 contained up to 128 thermistors covering a depth from 0.5 to 12 m with a vertical separation varying from 0.25 to 2 m (Marchenko et al, 2017b;see Fig. 2 therein).…”
Section: Equipmentmentioning
confidence: 99%
“…The front of Nordenskiöldbreen has retreated by 15-35 m/a since the end of the Little Ice Age, but retreat rates have been negligible since ∼2002 as the glacier is retreating on land (Allaart, 2016;Rachlewicz et al, 2007). Nordenskiöldbreen is a polythermal glacier ("type b" in Blatter & Hutter, 1991), with temperate conditions in the accumulation zone due to deep meltwater percolation and refreezing (Marchenko et al, 2016(Marchenko et al, , 2017Vega et al, 2016), and cold near-surface ice in the ablation area (Van Pelt et al, 2012). Nordenskiöldbreen is a polythermal glacier ("type b" in Blatter & Hutter, 1991), with temperate conditions in the accumulation zone due to deep meltwater percolation and refreezing (Marchenko et al, 2016(Marchenko et al, , 2017Vega et al, 2016), and cold near-surface ice in the ablation area (Van Pelt et al, 2012).…”
Section: Study Areamentioning
confidence: 99%
“…(Van Pelt et al, 2012). Nordenskiöldbreen is a polythermal glacier ("type b" in Blatter & Hutter, 1991), with temperate conditions in the accumulation zone due to deep meltwater percolation and refreezing (Marchenko et al, 2016(Marchenko et al, , 2017Vega et al, 2016), and cold near-surface ice in the ablation area (Van Pelt et al, 2012). Unlike neighboring outlet glacier Tunabreen, Nordenskiöldbreen is not a surge-type glacier, at least no surges have occurred since the termination of the Little Ice Age according to analysis of foreland landforms (Ewertowski et al, 2016).…”
Section: Study Areamentioning
confidence: 99%
“…Recent advances in firn modeling facilitated a move from empirical parameterizations of meltwater retention based on few climate parameter (Janssens & Huybrechts, 2000;Reijmer et al, 2012) to physical multilayer snow and firn models resolving multiple subsurface processes driven by weather observations (Charalampidis et al, 2015;Marchenko et al, 2017;Wever et al, 2014;Wever et al, 2016) or regional climate models (Langen et al, 2017;Steger et al, 2017). These models now allow identifying the contributions of various subsurface processes to a net observable change in firn structure and density and therefore allow a better understanding of the surface of the Greenland ice sheet and of its response to climate warming.…”
mentioning
confidence: 99%